A state-averaged orbital-optimized hybrid quantum-classical algorithm for a democratic description of ground and excited states

TL;DR

This paper introduces a NISQ-compatible hybrid quantum-classical algorithm, SA-OO-VQE, designed to accurately describe complex electronic features like conical intersections in molecules, crucial for chemical reactions.

Contribution

The paper presents a novel state-averaged orbital-optimized VQE method that effectively handles degenerate states, improving quantum simulations of complex chemical phenomena.

Findings

Successfully simulated conical intersections in a minimal Schiff base model

Demonstrated the method's ability to treat degenerate states on equal footing

Showed potential for accurate quantum chemistry simulations on NISQ devices

Abstract

In the Noisy Intermediate-Scale Quantum (NISQ) era, solving the electronic structure problem from chemistry is considered as the "killer application" for near-term quantum devices. In spite of the success of variational hybrid quantum/classical algorithms in providing accurate energy profiles for small molecules, careful considerations are still required for the description of complicated features of potential energy surfaces. Because the current quantum resources are very limited, it is common to focus on a restricted part of the Hilbert space (determined by the set of active orbitals). While physically motivated, this approximation can severely impact the description of these complicated features. A perfect example is that of conical intersections (i.e. a singular point of degeneracy between electronic states), which are of primary importance to understand many prominent reactions. Designing active spaces so that the improved accuracy from a quantum computer is not rendered useless is key to finding useful applications of these promising devices within the field of chemistry. To answer this issue, we introduce a NISQ-friendly method called "State-Averaged Orbital-Optimized Variational Quantum Eigensolver" (SA-OO-VQE) which combines two algorithms: (1) a state-averaged orbital-optimizer, and (2) a state-averaged VQE. To demonstrate the success of the method, we classically simulate it on a minimal Schiff base model (namely the formaldimine molecule CH2NH) relevant also for the photoisomerization in rhodopsin -- a crucial step in the process of vision mediated by the presence of a conical intersection. We show that merging both algorithms fulfil the necessary condition to describe the molecule's conical intersection, i.e. the ability to treat degenerate (or quasi-degenerate) states on the same footing.